Miembros: kittykat

HHH appears within the first 10 tosses: There are 10 possibilities for the location of the first H (tosses 1 through 10). For each of these possibilities, there are two remaining tosses that must be Hs (total of 2 * 10 = 20 outcomes).

TTT appears within the first 10 tosses: Similar to case 1, there are 20 outcomes (10 possibilities for the first T and two remaining tosses must be Ts).

The total number of successful outcomes for the complementary event is 20 (HHH) + 20 (TTT) = 40.

Since each outcome (sequence of tosses) has an equal probability (either H or T on each toss), the probability of any specific outcome is 1/2 raised to the power of the number of tosses (2^-# of tosses).

The total number of possible outcomes for 10 tosses is 2^10 (either H or T on each toss).

Therefore, the probability of the complementary event is:

Probability (complementary event) = (Favorable outcomes) / (Total possible outcomes) Probability (complementary event) = 40 / (2^10)

Probability of the Event:

The probability of the event we're interested in (tossing more than 10 times) is the complement of the complementary event.

Probability (event) = 1 - Probability (complementary event)

Since all outcomes are equally likely, the sum of the probabilities of all possible events must be 1.

Probability (event) = 1 - 40 / (2^10)

Simplifying the Fraction:

We can rewrite 2^10 as 1024.

Probability (event) = 1 - (40 / 1024)

Probability (event) = 1 - (5 / 128)

Probability (event) = 123/128

Therefore, the answer is 123/128.

kittykat9 may 2024

+1052

To solve this problem, let's first find the total number of possible pairs of cards that Professor Grok can draw. Since there are 4 colors and 7 numbers, there are $4 \times 7 = 28$ cards in total.

Now, let's find the number of pairs where the first card drawn is labeled with an even number and the second card drawn is labeled with a multiple of 3.

1. There are 7 even numbers among 1 to 7: 2, 4, 6.

2. There are 7 multiples of 3 among 1 to 7: 3, 6.

To find the number of pairs with the desired properties:

- For the first card, there are 7 even numbers, and for the second card, there are 7 multiples of 3.

- So, the total number of pairs with the desired properties is $7 \times 7 = 49$.

Now, to find the probability, divide the number of pairs with the desired properties by the total number of possible pairs:

\[\text{Probability} = \frac{\text{Number of pairs with desired properties}}{\text{Total number of possible pairs}} = \frac{49}{28 \times 27}\]

However, since Professor Grok is drawing without replacement, after the first card is drawn, there are only 27 cards left. So, the denominator should be $28 \times 27$.

Thus, the probability that the first card Grok draws is labeled with an even number, and the second card Grok draws is labeled with a multiple of 3 is:

\[\frac{49}{28 \times 27} = \frac{7}{108}.\]

kittykat9 may 2024

+1052

-1

Here's another way to solve this problem, focusing on proportionality within the parallelogram:

Proportions in Similar Triangles:

Since ABCD is a parallelogram, lines AD and BC are parallel. When line DE intersects line BC at point F, it creates two transversal lines. Because of this, corresponding angles on alternate sides of DE are congruent (alternate interior angles)

Therefore, triangles EAD and EBF are similar by Angle-Angle Similarity (AA).

Since the triangles are similar, the ratio of their areas is equal to the square of the ratio of their corresponding side lengths:

Area(EBF) / Area(EAD) = (length(BF) / length(AD))^2

Given Information:

We are given that the area of triangle EBF is 4 and the area of triangle EAD is 9. Plugging these values into the equation:

4 / 9 = (length(BF) / length(AD))^2

Proportionality in a Parallelogram:

In a parallelogram, opposite sides have the same length. Therefore, length(BF) = length(AE) and length(AD) = length(BC). Substituting these equalities into the equation from step 2:

4 / 9 = (length(AE) / length(BC))^2

Area of Parallelogram:

The area of a parallelogram is equal to the base times the height. Since AD is parallel to BC, the height of parallelogram ABCD is the same as the height of triangle EAD (considering side AE as the base). We can express this using proportionality:

Area(ABCD) ∝ length(BC) * height(EAD)

From step 3, we know the ratio between the base of triangle EAD (which is also a base of the parallelogram) and side BC of the parallelogram:

length(AE) / length(BC) = √(4/9) (taking the square root of both sides)

Combining Proportions:

Since the area of the parallelogram is proportional to the product of its base and height, and we know the ratio between the base and a side of the parallelogram, we can combine these proportions:

Area(ABCD) ∝ (√(4/9)) * height(EAD)

Note: We don't need to find the actual height of triangle EAD since it cancels out when solving for the relative area of the parallelogram.

Relative Area of Parallelogram:

Since the area of triangle EAD is a constant value (9) and the other factor in the proportion is a constant resulting from the given information, the area of parallelogram ABCD is also proportional to a constant value.

Therefore, relative to the area of triangle EAD, the area of parallelogram ABCD is:

Area(ABCD) ∝ √(4/9) * Area(EAD) = √(4/9) * 9 = 4

Scaling to Actual Area:

While the previous step gives us the relative area compared to triangle EAD, we can find the actual area by considering that the area of triangle EBF is given as 4.

Since triangles EAD and EBF are similar, the ratio of their areas is the square of the ratio of their corresponding side lengths (as established in step 1). Therefore, the area of triangle EAD is 4 times the area of triangle EBF:

Area(EAD) = 4 * Area(EBF) = 4 * 4 = 16

Now, we can use the relative area we found in step 6 to solve for the actual area of the parallelogram:

Area(ABCD) = √(4/9) * Area(EAD) = √(4/9) * 16

Area(ABCD) = 4 * 4 = 16.

kittykat20 abr 2024

+1052

Problem: Let a_1, a_2, a_3 be real numbers such that

|a_1 - a_2| + |a_2 - a_3| + |a_3 - a_1| = 100.
What is the largest possible value of |a_1 - a_2|?

Answer: 10

kittykat17 abr 2024

+1052

Here's how to find the radius of the circle:

Area of a Single White Sector:

We are given that the area of one white sector is 13π/54 square inches.

Proportion of White Sectors:

Since there are 21 sectors total and 3 are white, the white sectors represent 3/21 of the entire circle's area.

Full Circle Area:

To find the total area of the circle, we can divide the area of one white sector by its proportion (3/21) of the whole circle:

Total circle area = (Area of one white sector) / (Proportion of white sectors)

Total circle area = (13π/54 in²) / (3/21)

Circle Area Formula:

We know the area of a circle is calculated by πr², where r is the radius.

Equating Areas:

Since the total area we found represents the entire circle, we can equate it to the circle area formula:

πr² = (13π/54 in²) / (3/21)

Simplifying and Solving:

Cancel out common factors of π and simplify:

r² = (13 / 54) * (21 / 3) in²

r² = 13 in²

Take the square root of both sides (remembering that squaring can introduce extraneous solutions, so we'll check for those later).

r = √13 in ≈ 3.61 in (rounded to nearest hundredth)

kittykat17 abr 2024

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